ES2431322T3 - System and method for transferring calls between wireless networks of switched circuits and switched data packets - Google Patents

Abstract

A method of transferring a hybrid mobile terminal (10), operative to communicate through both wireless packet data networks (30) and switched circuits (20), from a service network of such networks that initially transports an existing call to a target of such networks (20, 30), characterized by generating a new call by said mobile terminal, which has an identifier of the predetermined called party, through the target wireless network (20, 30); accept a loop call through the wireless service network (20, 30) by said mobile terminal; and in response to the loop call, continue the existing call through the target wireless network (20, 30).

Description

System and method for transferring calls between wireless networks of switched circuits and switched data packets

Related Requests

This application claims the benefit of the US Provisional Patent Application. 60 / 643,625 filed on January 13, 2005.

Background

The present invention relates generally to the field of communication networks and in particular to a system and method for transferring a call between wireless networks of switched circuits and data packets.

The emerging technology for central networks in wireless communication systems is an all-IP, packet-based network. For example, the IP multimedia system (IMS) is an open industrial standard architecture for telecommunication operators to provide voice and multimedia communication services. The IMS network runs over the standard Internet Protocol (IP), providing both Voice over IP (VoIP) and data services, which include continuous broadcasting or broadcasting of audio and video, videoconferencing, games, file sharing, mail electronic, and the like. The IMS network supports both wireless packet data networks, such as CDMA 1x EV-DO, WLAN (WiFi), WiMAX, WCDMA, HSPDA, and the like, as well as wireless switched circuit networks, such as CDMA 1x, GSM, and WCDMA

While the migration to packet data networks is expected to continue, wireless circuit switched communication networks are widely deployed and widely used. A heterogeneous mix of wireless switched circuit networks and data packets will exist in the field for years to come.

Mobility management is a key aspect of wireless communication systems, necessary to maintain communications with mobile terminals as users move in all different geographic areas. Mobile Assisted Transfer (MAHO) is a well known element of mobility management. At MAHO, mobile terminals report channel conditions, desired data rates, pilot intensities signals from adjacent radio base stations, and similar to a service base station, which, using this information as well as the relative load between base stations adjacent, determines if, when, and to which base station to transfer a mobile terminal. Transfer within a system is a fundamental operational aspect of any wireless communication system.

The transfer between systems, however, can be problematic for various reasons. First, mobile terminals must be developed and deployed so that they are able to participate in communications with both wireless switched circuit networks and data packets. Additionally, in most deployments, wireless switched circuit networks and data packets operate in different frequency bands. There are hybrid mobile terminals that can operate in both frequency bands simultaneously; however, a smooth transfer between systems is impossible due to the different radio technologies used. Additionally, network protocols in switched circuit systems and data packets do not directly support a transfer between systems.

From WO 2004/082219 A a dual mode remote unit is known that is capable of receiving signals both in a cellular system as well as in a wireless local area network. A method of switching a telephone call comprises receiving a SIP invite message about data which path carries data from a cellular network, the SIP invite that specifies a called party and a calling party, initiating a first stage of a voice call. to the called party, initiating a second stage of the voice call to the calling party, and switching the first stage to the second stage to establish the voice call between the two.

Compendium

In one or more embodiments, the present invention relates to transferring a hybrid mobile terminal between wireless packet data networks and switched circuits. The hybrid mobile terminal participates in an existing call through a wireless network service. The mobile terminal places a new call through the wireless networks target, the new call that has an identifier of the predetermined called party. In response to the identifier of the called party, the call is converted to a loop call directed to the mobile terminal through the wireless service network, establishing a call path through the target wireless network. The mobile terminal accepts the loop call, and directs the existing call to connect to the call path through the target wireless network. The existing call through the original network is then abandoned.

In one embodiment, the present invention relates to a method of transferring from a service network of a wireless packet data network or circuit switched to an objective of the networks, for a hybrid mobile terminal capable of communications through both networks. and that participates in an existing call through wireless service networks. A new call is received from the mobile terminal through the target wireless network, the new call having an identifier of the predetermined called party. In response to the identifier of the called party, the new call is routed back to the mobile terminal through the wireless service network. The existing call connects to the mobile terminal through the target wireless network.

In another embodiment, the present invention relates to a method of transferring a hybrid mobile terminal, operative to communicate through both wireless packet data networks and switched circuits, from a service network of such networks that initially carries a call existing to an objective of such networks. A new call, which has an identifier of the default called party, is generated through the target wireless network. A loop call is accepted through the wireless service network. In response to the loop call, the existing call is continued through the target wireless network.

In yet another embodiment, the present invention relates to a wireless switched circuit network, which includes a subscriber database that maintains a plurality of subscriber profiles and at least one dummy subscriber profile having a Mobile Directory Number ( MDN) default and that identifies a call directed to the default MDN as a call in transfer loop. The wireless circuit switched network also includes an operational network node to redirect a call in transfer loop to the mobile terminal that originated the call.

In yet another embodiment, the present invention relates to a wireless network of data packets, which includes a Public Service Identifier Application Server (PSI AS) operative to redirect a call in transfer loop to the mobile terminal that originated the call. The wireless packet data network also includes an operational network node to receive an Initial Address Message (IAM) from a wireless switched circuit network, the IAM that has a predetermined MDN as the identifier of the called party, and also operational to convert the identifier of the called party from the default MDN to the sip: uri address of the PSI AS.

Brief description of the drawings

Figure 1A is a network diagram of an existing call through a wireless packet data network.

Figure 1B is a network diagram of the existing call and a loop call through a wireless network of switched circuits.

Figure 1C is a network diagram that follows a transfer of the existing call from the wireless packet data network to the switched circuit network.

Figures 2A-2B are a signaling diagram of the transfer between systems of Figures 1A-1C.

Figures 3A-3C are a flow chart of the transfer between systems of Figures 1A-1C.

Figure 4A is a network diagram of an existing call through a wireless switched circuit network.

Figure 4B is a network diagram of the existing call and a loop call through a wireless packet data network.

Figure 4C is a network diagram that follows the transfer of the existing call from the wireless network of switched circuits to that of data packets.

Figure 5 is a signaling diagram of the transfer between systems of Figures 4A-4C.

Figures 6A-6B are a flow chart of the transfer between systems of Figures 4A-4C.

Detailed description

In one or more embodiments, the present invention relates to a system and method of transferring a hybrid mobile terminal between wireless packet data networks and switched circuits. As used herein, a hybrid mobile terminal refers to a mobile device that has radio transceivers, functionality, and if authorization is necessary, to participate in voice and / or data communications with both a wireless packet network. of data as a wireless network of switched circuits. Due to the different operating frequencies and a lack of protocols between the networks themselves, it is not currently possible to transfer an existing call from one network to the other, as may be necessary if the hybrid mobile terminal moves from a geographical area served by a network within one area served by the other.

Any new transfer method should work equally well in any direction. That is, it must provide transfer from a wireless network of data packets to a wireless network of switched circuits, as well as from the wireless network of switched circuits to that of data packets. In the following discussion, the “service” wireless network is the network through which the existing call to the hybrid mobile terminal is routed, and it can be either a wireless network of data packets or a wireless network of switched circuits. The “objective” wireless network is the other network, through which the call will be connected following the transfer procedure.

One way to establish a call path through the target wireless network is for the corresponding functionality in the mobile terminal to place a call through the target wireless network to its functionality corresponding to the service network. The existing call can later be connected to the newly established call path. That is, on the side of data packets of the hybrid mobile terminal places a call on the switched circuit side of the same hybrid mobile terminal, or vice versa. The call is known herein as a loop call.

However, most existing networks interpret a call to the origin - that is, a call where the Called Party Number (CgPN) and the Called Party Number (CdPN) are the same - as a call to access to the user's voice mailbox. In this way, to work within existing networks, the CgPN and the CdPN must be different. In wireless switched circuit networks, the Mobile Directory Number (MDN) of the hybrid mobile terminal is inserted in the Initial Address Message (IAM) as the CgPN (also known as Number A) by the Mobile Switching Center (MSC) serving the mobile terminal, as part of the Line Identification functionality. Therefore, altering the CgPN is not an option.

According to one or more embodiments of the present invention, a loop call is established by a hybrid mobile terminal by placing a call having a Transfer Routing Number (TRN) such as the CdPN. A single TRN is defined for each network: TRNpd for the wireless packet data network and TRNcs for the wireless switched circuit network. When a network (target) receives a call request from a hybrid mobile terminal where the CdPN is the TRN for that network (and the CgPN = MDN), the network recognizes the call as a loop call, and routes the call back to the hybrid mobile terminal through another wireless (service) network. This can be accomplished, for example, by exchanging the identifiers of the called and calling party (ie, CgPN = TRN and CdPN = MDN), and routing the call to the wireless service network.

The call arrives at the hybrid mobile terminal through the wireless service network. The hybrid mobile terminal recognizes the call in loop under the TRN and / or MDN. The hybrid mobile terminal accepts the call, and transfers the existing call to its functionality associated with the target wireless network. The wireless service network (or the hybrid mobile terminal) can then connect the existing call to the established call path through the target wireless network, and leaves the stage of the existing call through the wireless service network, effectively transferring the call from the wireless service network to the target.

Transfer of the data packet network to the switched circuit network

Figure 1 depicts a hybrid mobile terminal 10, comprising both an Access Terminal (AT) functionality of wireless packet data network and Mobile Station (MS) wireless switched circuit network. The hybrid AT / MS 10 is in a Roaming Area 12, in which a wireless network of switched circuits 20 and a wireless network of data packets 30 are operative.

The wireless switched circuit network 20 comprises a Mobile Switching Center (MSC) 22, connected to one or more Switched Circuit Base Station Controllers (BSC of CS) 24 that provide communication services to one or more mobile stations (no show). The MSC 22 routes voice and data over switched circuit network connections between the BSC of CS 24 and numerous other network nodes (not shown). The BSC of CS 24 includes or controls one or more base stations or base station transceivers (not shown) that include the transceiver resources necessary to support radio communication with mobile stations, such as modulators / demodulators, baseband processors, amplifiers of radio frequency (RF) power, antennas, and the like.

The wireless data packet network 30 comprises a Data Packet Switching Node (PDSN) 32 connected to one or more Data Packet Base Station Controllers (PD BSCs) 34 that provide data packet communication services to one or more access terminals, such as the AT side of the hybrid AT / MS 10. The PDSN 32 routes the data packets between the BSC of PD 34 and other data packet networks, such as the Media System network IP (IMS) 40. The BSC of PD 34 includes or controls one or more base stations similar to the BSC of CS 24, but provides packet data communications on high bandwidth channels, shared to the ATs.

Both wireless networks 20, 30 are connected to an IMS 40 network. The IMS is an open, general-purpose industry standard for voice and multimedia communications over packet-based IP networks 40. The IMS 40 network includes one or more Application Servers (AS) 42 that provide various services (continuous broadcast or broadcast of audio or video, click to talk, videoconferencing, games, file sharing, email, and the like). In particular, a Telephony AS (TAS) 50 provides telephone communications services, as described in more detail herein. Another AS within IMS 40 is a Public Service Identifier (PSI) AS 48. The PSI AS 48 is a generic AS that handles session transfer between IP connectivity points for a specific terminal. The PSI AS 48 handles transfers between systems within a system.

Communications between nodes within the IMS 40 network use the Session Initiation Protocol (SIP). SIP is a signaling protocol for conference, telephony, presence, event notification, instant messaging, and the like online. SIP uses a stable long-term identifier, the Universal Resource Indicator (URI) of SIP.

The PSI AS 48 and the TAS 50 are connected to a Call-Service Session Control Function (S-CSCF) 44. The S-CSCF 44 starts, manages, and terminates multimedia sessions between IMS 40 terminals. The S -CSCF 44 can be connected to an optional CSCF-Interrogation (I-CSCF) 46. I-CSCF 46 is a SIP broker located at the edge of an administrative domain. The I-CSCF (or S-CSCF if an I-CSCF is not present) is connected to a CSCF-Intermediary (P-CSCF) 52. The P-CSCF 52 is a SIP intermediary that is the first point of contact for the IMS 40.

Both the PDSN 32 of the wireless packet data network 30 and a Media Gateway Control Function (MGCF2) 54 maintain SIP connections to the P-CSCF 52. The MGCF2 54 controls a media gateway (MGw2) 56, connected with the MSC 22 of the wireless switched circuit network 20 through a dedicated transfer trunk. The MGCF2 54 maintains an ISUP connection with the MSC 22.

Figure 1A depicts the hybrid AT / MS 10 participating in a voice call with a party in the Public Switched Telephone Network (PSTN) 62. The PSTN 62 is connected to the IMS 40 network via a PSTN 60 interface that includes a MGCF1 66 which controls an MGw1 64. The MGw1 64 is connected to PSTN 62 over a time division multiplexed (TDM) link. The MGw1 64 translates coded voice packets or 64 kbps Coded Pulse Modulated (PCM) voice signals from switched circuits from PSTN 62 to coded voice packets, such as for example Enhanced Variable Rate CODEC (EVRC) packets , which are then transmitted through a Real-time Transport Protocol (RTP) or Internet Protocol (IP) to other nodes in the IMS 40 network.

The call represented in Figure 1A was established by, and is maintained by, the TAS 50. The TAS 50 serves as a Reciprocal Guarantee User Agent (B2BUA). A B2BUA is a logical SIP-based entity that can receive and process SIP INVITE messages as a SIP User Agent Server (UAS). The B2BUA also acts as a SIP User Agent Client (UAC) that determines how the request should be answered and how to initiate outgoing calls. Unlike a SIP intermediary server, the B2BUA maintains full call status and participates in all call requests. In particular, for the call in Figure 1A, the B2BUA controls two SIP dialogs: a first dialogue between MGCF1 66 and TAS 50; and a second dialogue between the TAS 50 and the AT (IMS client) side of the hybrid AT / MS 10. In the media plane or user plane, the encoded voice packets are transmitted from the MGw1 64 to the PDSN 32, and they are transmitted from the BSC of PD 34 over the air interface to the hybrid AT / MS 10. The voice packets in the opposite direction follow the reverse path.

As the hybrid AT / MS 10 physically moves beyond the radio transceiver resources of the BSC of PD 34, the hybrid AT / MS 10 indicates poor channel conditions to the BSC of PD 34, such as requesting a data rate of less than through the Data Rate Control Index (DRC). When the hybrid AT / MS 10 reports sufficiently poor channel conditions, the PDC BSC 34 determines whether to transfer the hybrid AT / MS 10 to another base station of the wireless network.

If the wireless packet data network 30 is of limited geographic extent, and the hybrid AT / MS 10 is on the edge of its service area, it is likely that the hybrid AT / MS 10 can be served by a wireless circuit network switched 20, which are more widely deployed. However, the wireless packet data network 30 and the wireless switched circuit network 20 may not implement protocols for transfer between systems.

According to one or more embodiments of the present invention, the transfer of a hybrid AT / MS 10 from the wireless packet data network 30 to the wireless switched circuit network 20 is facilitated by having the hybrid AT / MS 10 place a call from the side of the MS, via the wireless network of switched circuits 20, to its side of the AT - known herein as a loop call. The loop call establishes a third communication dialogue between the TAS 50 and the MS side of the hybrid AT / MS 10 - via the wireless circuit switched network 20 - to which the first dialogue can be connected (MGw1 - TAS) of the existing call, to effect a transfer between systems. The second dialogue (TAS - AT) can then be left. This process is described with reference to the signal flow diagram of Figure 2, and the flow chart of Figure 3, where the numbering of the method steps and network events is consistent.

As discussed above, hybrid AT / MS 10 initially participates in an existing voice call. TAS 50 is a B2BUA, which maintains a first dialogue between MGw1 64 and TAS 50, and a second dialogue between TAS 50 and the AT side of the AT / MS 10 (block 100). If necessary, the MS functionality within the AT / MS 10 is registered with the wireless switched circuit network 20, according to standard procedures well known in the art (block 102). The MS side on the AT / MS 10 then initiates a call through the wireless switched circuit network 20, with the CdPN = TRNpd (block 104). This identifies the call to network 40 as a loop call used to initiate a transfer.

The MSC 22 places the MDN of the AT / MS 10 in the CgPN field of an Initial Address Message (IAM) and sends the IAM to the MGCF2 54 (block 106). MGCF2 54 performs an ENUM conversion on the TRNpd to generate a PSI AS of sip: uri (block 108). ENUM is a protocol that converts fully qualified PSTN telephone numbers to fully qualified IMS URIs. The default TRNpd value is a reserved telephone number that identifies a call placed for it as a loop call used for effective transfer between systems. MGCF2 54 places the PSI AS sip: uri in the R-URI field (A) of a SIP INVITE message, and places the information in the IAM CgPN field (i.e., the MDN) in the P-Certified ID field (verified From) of the SIP INVITE message.

The MGCF2 54 sends the SIP INVITE message to the IMS 40 network, where it is routed to the PSI AS 48 (block 110). The PSI AS 48 exchanges the values of the R-URI and P-Certified ID fields - that is, the identifiers of the called and calling party - thus redirecting the call back to the originating AT / MS 10 (block 112 ). The PSI AS 48 additionally performs an ENUM conversion in the MDN, so that the call back to the AT / MS 10 is routed through the wireless packet data network 30. The PSI AS 48 forwards the SIP INVITE message modified to S-CSCF 44 (block 114). A trigger on S-CSCF 44 causes the SIP INVITE message to be routed to TAS 50 (block 116).

In response to the caller ID, that is, the certificate ID header P which is the PSI AS 48, the TAS 50 recognizes the call in loop, and creates a third dialogue: between the TAS 50 and the MGCF2 54 The TAS 50 sends a SIP 200 OK message containing information from the Session Description Protocol (SDP) for MGw1 64 to S-CSCF 44 (block 120), which forwards it to MGCF2 54 (block 122). The MGCF2 sends a Reply Message (ANM) to the MSC 22 (block 124). This establishes the third dialogue, through the wireless network of switched circuits 20 (block 126). MGCF2 54 sends an acknowledgment message confirming the establishment of the third dialogue to S-CSCF 44 (block 128), which forwards it to TAS 50 (block 130). The existing call through the wireless packet data network 30 and the loop call through the wireless switched circuit network 20 are shown in Figure 1B.

After receiving recognition of the third dialogue, the TAS 50 changes the first dialogue (MGw1 - TAS) by sending a SIP UPDATE message informing the MGCF1 66 to direct the MGw1 64 to send / receive media from the MGw2 56. This SIP message UPDATE is sent to S-CSCF 44 (block 132), which forwards it to MGCF1 66 (block 134).

At the same time, the TAS 50 releases the second dialogue (TAS - AT) by routing a BYE message to the IMS client (the AT side of the AT / MS 10). TAS 50 sends the BYE message to S-CSCF 44 (block 136), which forwards it to AT / MS 10 (block 138). After receiving the BYE message, the AT side of the AT / MS 10 transfers voice for the existing call to its MS functionality, transmitting and receiving voice signals through the wireless circuit switched network 20.

Meanwhile, MGCF1 66 confirms the update to the existing call by sending an SIP 200 OK message to S-CSCF 44 (block 142), which is routed to TAS 50 (block 144). At this time the voice is connected between MGw1 64 and MGw2 56.

Finally, the IMS client (on the AT side of the AT / MS 10), confirms the release of the second dialogue (TAS - AT) by sending a SIP 200 OK message to S-CSCF 44 (block 146), which forwards it to the TAS 50 (block 148). The transfer between systems is complete, and the AT / MS 10 continues the existing call through the wireless switched circuit network 20, using its MS functionality. The media plane for the transferred call is represented in Figure 1C. The voice signals of the PSTN 62 are translated into voice packets encoded by the MGw1 64, and travel over the RTP or IP to the MGw2 56. The MGw2 56 translates the encoded voice packets into the 64-bit PCM format of the link backspace of the wireless circuit switched network 20, and transmits the signals to the MSC 22. The MSC 22 transmits the voice signals to the BSC of CS 24, which transmits them on a dedicated channel to the AT / MS 10. The voice signals in The opposite direction follows the reverse path.

Network transfer from switched circuits to packet data network

Figure 4A depicts a hybrid AT / MS 10 participating in an existing call with a party in the PSTN 62 through a wireless circuit switched network 20 in a roaming area 12. The wireless circuit switched network 20 comprises an MSC Visiting (VMSC) 22 and a BSC of CS 24. Also within roaming area 12 is a wireless packet data network 30 comprising a PDSN 32 and a BSC of PD 34. The wireless packet data network 30 is connected to an IMS 40 network through a P-CSCF 52. The IMS 40 network includes one or more AS 42, an S-CSCF 44, an I-CSCF 46, a TAS 50, and an MGCF 54 that controls an MGw 56. All components of the IMS 40 network were described above.

The MGCF 54 maintains an ISUP signaling connection to an MSC Gateway (GMSC) 58, which is in the local area of the wireless circuit switched network 20. The GMSC 58 is connected to a Subscriber Location Register (HLR) 60 and a Service Control Point (SCP) 61. The GMSC 58 additionally maintains connections to other network nodes, such as PSTN 62.

As depicted in Figure 4A, and represented in the signal diagram of Figure 5 and the flowchart of Figure 6 (where the steps of the method and network signaling are consistently numbered), the AT / MS 10 participates in an existing call, using its MS functionality, through the wireless circuit switched network 20 (block 150). Voice signals travel from a telephone on the PSTN 62, through the GMSC 58 in the local area, through the MSC 22 in the roaming area, and are transmitted to the AT / MS 10 on a dedicated channel over the air interface of circuits switched by the BSC of CS 24. The voice signals in the opposite direction followed the reverse path.

As the AT / MS 10 physically moves beyond the radio transceivers of the BSC of CS 24, a transfer to the wireless packet of data packets 30 may become necessary. According to one or more embodiments of the present invention, such a transfer It can be facilitated by the hybrid AT / MS 10 by placing a loop call from its AT functionality, via the wireless packet data network 30, to its MS functionality. This establishes a call dialogue through the wireless packet data network 30, to which the existing call can be connected. Then disconnecting the call through the wireless network of switched circuits 20, the AT / MS 10 will have a change of settlement and transfer between systems.

If necessary, the AT side of the AT / MS 10 is registered with the IMS 40 network through the wireless packet data network 30 (block 152). The AT initiates a call through the wireless packet data network 30 by issuing a SIP INVITE message to S-CSCF 44, with CgPN = MDN and CdPN = TRNcs (block 154). In response to a trigger, S-CSCF 44 forwards the SIP INVITE message to TAS 50 (block 156).

In response to the recognition of the TRNcs, the TAS 50 identifies the call request as a loop call for a transfer between systems. The TAS 50 thus knows how to route the call through the wireless network of switched circuits 20 (block 158). The TAS 50 generates a SIP INVITE message with CgPN = MDN, CdPN = TRNcs, and ROUTE = MGCF and sends the SIP INVITE message to S-CSCF 44 (block 160), which forwards it to MGCF 54 (block 162). The MGCF 54 generates an Initial Address Message (IAM) with the identifiers of the called and calling party, and sends the IAM to GMSC 58 (block 164).

According to normal roaming circuit network roaming procedures, the GMSC 58 accesses the HLR 60 which found out the location of the called party (TRNcs). A dummy subscriber entry in the HLR 60, which has the MDN = TRNcs, includes Wireless Intelligent Network (WIN) data specified in such a way that it directs the GMSC 58 to a particular Service Control Point (SCP) 61. When the GMSC 58 accesses SCP 61, SCP 61 identifies the loop call as part of a transfer between systems recognizing the TRNcs as the identifier of the called party. The SCP 61 exchanges the identifiers of the called and calling party, thus routing the loop call to the originating AT / MS 10. SCP 61 then directs GMSC 58 to continue the call establishment. The GMSC 58 notes that the CdPN has changed, interprets this as a “call forwarded”, and re-accesses the HLR 60 to find out the voice of the called party (now the MDN) (block

166).

The GMSC 58 places the AT / MS 10, and sends an IAM signal to the VMSC 22 (block 168). VMSC 22, aware that the AT / MS 10 participates in the existing voice call, sends a Call Waiting signal to the AT / MS 10 (block 170). The AT / MS 10 recognizes the loop call (by inspection of CgPN = TRNcs), suppresses any Call Waiting alert that would normally be issued to the user, and accepts the call (block 172). At this point, the loop call from the AT side through the wireless packet data network 32 on the MS side of the AT / MS 10 is established (block 174), as shown in Figure 4B.

The AT / MS 10 sends a UNIR command through the wireless switched circuit network 20, directing the existing call to connect the loop call through the wireless packet data network 30 (block 176). The stage of the loop call to the wireless circuit switched network 20 is disconnected, making a transfer between systems of the AT / MS 10 from the wireless network of switched circuits 20 to the wireless packet data network 30, as shown in Figure 4C. The voice signals travel from a telephone on the PSTN 62 to the MGw 56. The MGw 56 converts the voice into coded voice packets that are transmitted over RTP or IP to the PDSN 32. The BSC of PD 34 then transmits the voice packets over a shared channel next to the AT of the AT / MS 10. The voice in the opposite direction follows the reverse path.

Although the present invention has been described herein with respect to particular features, aspects and embodiments thereof, it will be apparent that numerous variations, modifications, and other embodiments are possible within the scope of the present invention as defined by the claims. attached.

Claims (18)

1. A method of transferring a hybrid mobile terminal (10), operative to communicate through both wireless packet data networks (30) and switched circuits (20), from a service network of such networks that initially transports a existing call to a target of such networks (20, 30), characterized by generating a new call by said mobile terminal, which has an identifier of the predetermined called party, through the target wireless network (20, 30); accept a loop call through the wireless service network (20, 30) by said mobile terminal; and in response to the loop call, continue the existing call through the target wireless network (20, 30).

2.

The method of claim 1 wherein accepting a loop call through the wireless service network comprises accepting the loop call in response to the caller ID of the calling party in the loop.

3.

The method of claim 2 wherein the identifier of the calling party of the loop call is the identifier of the predetermined called party of the new call.

Four.

The method of claim 1 wherein the identifier of the predetermined called party is a unique Transfer Routing Number for a transfer functionality in the target wireless network.

5.

The method of claim 4 wherein the Transfer Routing Number is a fictional operative subscriber profile to direct the new call to a predetermined node in the target network for transfer processing.

6.

The method of claim 1 further comprising terminating the existing call through the wireless service network.

7.

A wireless network of switched circuits (20), comprising:

a subscriber database (60) that maintains a plurality of subscriber profiles and at least one dummy subscriber profile that has a predetermined Mobile Directory Number, MDN and that identifies a call directed to the predetermined MDN as a loop call transfer; Y a network node (48) operative to redirect a call in transfer loop to the mobile terminal (10) that originated the call.

8.

The network of claim 7, wherein the network node (48) redirects the calls in transfer loop to the originating mobile terminal (10) by exchanging the identifiers of the called and calling party.

9.

The network of claim 7 wherein the network node is a Service Control Point, SCP.

10.

The network of claim 9 further comprising an MSC Mobile Switching Center (22) that receives an Initial Address Message, IAM, from a hybrid mobile terminal (10) through a wireless data packet network (30), the IAM that has the identifier of the party calling the MDN of the hybrid mobile terminal (10), and which has the identifier of the party called the predetermined MDN.

eleven.

The network of claim 10 wherein the MSC (22) is operative to route the IAM to the SCP in response to the dummy subscriber profile in the subscriber database.

12.

The network of claim 11 wherein the SPC is operative to place the hybrid mobile terminal MDN

(10) in the caller ID, place the default MDN in the caller ID, and to return the modified IAM to the MSC.

13.

The network of claim 12 wherein the MSC (22) is operative to route the modified IAM to the hybrid mobile terminal through the wireless circuit switched network.

14.

The network of claim 7 wherein the default MDN is a Transfer Routing Number, TRN, unique to the wireless switched circuit network (20).

fifteen.

A wireless network of data packets (30), comprising:

a Public Service Identifier Applications Server, hereinafter called PSI AS, (48) operative to redirect (112) a call in transfer loop to the mobile terminal (10) that originated the call; a network node (54) operative to receive an Initial Address Message, IAM, from a wireless switched circuit network (20), the IAM having a Mobile Directory Number, MDN, predetermined as the identifier of the called party, and also operative to convert (108) the identifier of the called party from the predetermined MDN to the sip: uri address of the PSI AS.

16.

The wireless packet data network of claim 15 wherein the PSI AS (48) redirects a transfer loop call to the originating mobile terminal by exchanging (112) the identifiers of the called and calling party.

17.

The wireless packet data network of claim 16 wherein the PSI AS (48) places the address

5 sip: PSI AS uri (48) in a P-Certificate ID field of a SIP INVITE message, places an ENUM conversion of the source mobile terminal MDN in an R-URI field of the SIP INVITE message, and propagates ( 114) the SIP INVITE message through the wireless packet data network (30). 18. The wireless packet data network of claim 17 further comprising a Telephone Application Server, TAS, (50) operative to receive the SIP INVITE message from the PSI AS (48) and, in 10 response to the sip: uri of the PSI AS (48) in a P-Certificate ID field, to establish a dialogue with the originating mobile terminal (10) through the wireless circuit switched network (20).